Pooling distributed storage nodes that have specialized hardware

ABSTRACT

Distributed storage nodes having specialized hardware can be pooled for servicing data requests. For example, a distributed storage system can include a group of storage nodes. The distributed storage system can determine a subset of storage nodes that include the specialized hardware based on status information received from the group of storage nodes. The specialized hardware can be preconfigured with specialized functionality. The distributed storage system can then generate a node pool that includes the subset of storage nodes with the specialized hardware. The node pool can be configured to perform the specialized functionality in relation to a data request.

TECHNICAL FIELD

The present disclosure relates generally to distributed storage systems.More specifically, but not by way of limitation, this disclosure relatesto pooling storage nodes of a distributed storage system that havespecialized hardware, such as hardware with built-in compression orencryption capabilities.

BACKGROUND

Distributed storage systems can include storage nodes in communicationwith each other over a network for synchronizing, coordinating, andstoring data. The storage nodes can work together so that thedistributed storage system behaves as one storage system. Distributedstorage systems can implement block storage, file storage, or objectstorage techniques.

There are numerous advantages to using distributed storage systems, suchas improved scalability, redundancy, and performance. In particular,distributed storage systems can be easily scaled horizontally, in thesense that they can combine many storage nodes into a single, sharedstorage system. Distributed storage systems can also store many copiesof the same data for high availability, backup, and disaster recoverypurposes. Additionally, some distributed storage systems can executecompute workloads on the same storage nodes that are also used to storedata, thereby yielding a hyper-converged infrastructure that is highlyefficient.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a block diagram of an example of a distributed storage systemaccording to some aspects of the present disclosure.

FIG. 2 is a sequence diagram of an example of a process for enablingspecialized functionality on a storage node according to some aspects ofthe present disclosure.

FIG. 3 is a block diagram of an example of data migration in adistributed storage system according to some aspects of the presentdisclosure.

FIG. 4 is a block diagram of another example of a distributed storagesystem according to some aspects of the present disclosure.

FIG. 5 a flow chart of an example of a process for pooling distributedstorage nodes according to some aspects of the present disclosure.

DETAILED DESCRIPTION

A distributed storage system can include storage nodes formed fromrelatively heterogeneous servers in communication with each other over anetwork, such as a local area network. Some of the storage nodes mayhave specialized hardware. Specialized hardware is a piece of hardwarethat is preconfigured by a manufacturer to implement specializedfunctionality, prior to receipt of the specialized hardware by an enduser. For example, the specialized hardware can include specializedcircuitry configured to implement the specialized functionality. Thespecialized circuitry may include a custom or semi-custom integratedcircuit with a special hardware design or firmware specifically tailoredfor performing the specialized functionality, where the specializedcircuitry is built into the specialized hardware by a manufacturerduring a manufacturing process. Thus, specialized hardware is differentfrom generic hardware on which aftermarket software is installed by theend user to implement the specialized functionality. The specializedfunctionality can be functionality that is supplemental to the mainpurpose of the piece of hardware. By way of example, the specializedhardware can include a storage adapter, a storage device, aninput/output (I/O) interface, or a processing device, where thespecialized hardware has appropriate circuitry built-in to implementspecialized functionality such as data encryption, data compression, andchecksum calculation capabilities. As one particular example, thespecialized hardware can be a self-encrypting hard drive with inlinedata-encryption capabilities. Using specialized hardware to perform thespecialized functionality can be faster and more robust than executingaftermarket software on generic hardware.

While some storage nodes may have the specialized hardware, otherstorage nodes may not. In such situations, the distributed storagesystem may operate as if all of the storage nodes lack the specializedhardware, since distributed storage systems generally operate on thebasis of the lowest common denominator. As a result, the distributedstorage system may not implement the specialized functionality of thespecialized hardware, even though the specialized functionality couldimprove the distributed storage system.

Some examples of the present disclosure can overcome one or more of theabovementioned problems by identifying storage nodes in a distributedstorage system that have specialized hardware with specializedfunctionality, enabling the specialized functionality on the storagenodes, grouping the storage nodes together into a pool of storage nodes(“node pool”) that have the specialized functionality enabled, and usingthe node pool to utilize the specialized functionality in relation todata requests. The data requests can include read requests for readingdata, write requests for writing data, or both. Grouping the storagenodes in this way can prevent the data requests from being divided upamong some storage nodes that have the specialized hardware and otherstorage nodes that lack the specialized hardware, so that the datarequests arrive at a node pool in which all of the storage node membershave the specialized hardware or none of the storage node members havethe specialized hardware. With the data requests arriving at a node poolin which all of the storage nodes have the specialized hardware, thedistributed storage system can leverage the specialized functionality toachieve various improvements, such as improvements to data security andthroughput.

One particular example can involve a distributed storage system, such asCeph Storage by Red Hat®. The distributed storage system can includehundreds or thousands of storage nodes. Each storage node can determineif it has specialized hardware capable of performing specializedfunctionality, such as data encryption, data compression, or both. Eachstorage node may determine if it has the specialized hardware byscanning its hardware. For example, a storage node can analyze itshardware upon booting up to determine if the specialized hardware isconnected. As another example, a storage node may periodically analyzeits hardware at predefined intervals to determine if the specializedhardware is connected. As yet another example, a storage node mayanalyze its hardware in response to an event determine if thespecialized hardware is connected. After scanning their hardware, thestorage nodes can then transmit status communications indicating whetheror not they have the specialized hardware capable of performing thespecialized functionality.

A centralized management node of the distributed storage system canreceive the status communications from the storage nodes. Based on thestatus communications, the management node can determine a subset of thestorage nodes that have the specialized hardware. The management nodemay then transmit communications to the subset of storage nodes forcausing the storage nodes to enable the specialized functionality.Alternatively, the storage nodes may automatically enable thespecialized functionality upon discovering that they are connected tothe specialized hardware. Either way, the specialized functionality canbe enabled on the storage nodes.

Next, the management node can assign the storage nodes in the subset tothe same node pool. As a result, the node pool may only contain storagenodes with specialized hardware capable of performing the specializedfunctionality. The node pool can then be used to service data requests,so that the specialized functionality can be performed in relation tothe data requests. Such node pools may be considered higher-tiered poolswith better performance or data protection, given their specializedfunctionality. Thus, a service provider that is selling access to thedistributed storage system may charge higher fees for using the nodepool than for other node pools, such as node pools that lack specializedhardware with the specialized functionality.

These illustrative examples are given to introduce the reader to thegeneral subject matter discussed here and are not intended to limit thescope of the disclosed concepts. The following sections describe variousadditional features and examples with reference to the drawings in whichlike numerals indicate like elements but, like the illustrativeexamples, should not be used to limit the present disclosure.

FIG. 1 is a block diagram of an example of a distributed storage system100 according to some aspects of the present disclosure. The distributedstorage system 100 includes storage nodes 102 a-e. The storage nodes 102a-e may be physical servers for storing data.

Some storage nodes 102 a-c can have specialized hardware 108 a-c, whileother storage nodes 102 d-e may lack the specialized hardware. Examplesof the specialized hardware 108 a-c can include a storage adapter forinteracting with storage devices, a storage device such as a hard diskor solid-state drive, a processing device such as a central processingunit (CPU) or graphics processing unit (GPU), or an I/O interface suchas a peripheral component interface (PCI) card. The specialized hardware108 a-c may be internal to the storage nodes 102 a-c or external andcoupled to the storage nodes 102 a-c. The specialized hardware 108 a-cis configured to implement specialized functionality. Examples of thespecialized functionality can include data compression/decompressioncapabilities, data encryption/decryption capabilities, checksumcalculation capabilities, or any combination of these. The specializedfunctionality may be selectively enabled and disabled.

In some examples, the storage nodes 102 a-e can each analyze theirhardware to determine if they have a corresponding piece of specializedhardware. For example, storage nodes 102 a-c may analyze their hardwareand determine that the specialized hardware 108 a-c is attached. Andstorage nodes 102 d-e may analyze their hardware and determine that theylack the specialized hardware. The storage nodes 102 a-e may analyzetheir hardware to determine if they have the specialized hardware inresponse to any suitable event. For example, the storage nodes 102 a-emay each analyze their hardware to detect the presence of a piece ofspecialized hardware in response to a boot up event. As another example,the storage nodes 102 a-e may each analyze their hardware to detect thepresence of the specialized hardware in response to the passage of apredefined amount of time, such as one hour. As yet another example, thestorage nodes 102 a-e may each analyze their hardware to detect thepresence of the specialized hardware in response to a request 110 from amanagement node 112 of the distributed storage system 100. One exampleof such a request 110 is shown in FIG. 1 , but the management node 112can transmit similar types of requests to many or all of the storagenodes 102 a-e.

After analyzing their hardware, the storage nodes 102 a-e can generaterespective status information indicating whether or not they have thespecialized hardware. Each of the storage nodes 102 a-e can thentransmit a status communication that includes the respective statusinformation over a network to the management node 112. The network maybe a local area network or the Internet. One example of such a statuscommunication 114 with status information 116 is shown in FIG. 1 , butmany or all of the storage nodes 102 a-e may transmit similar types ofstatus communications to the management node 112.

The management node 112 is configured to manage one or more aspects ofthe distributed storage system 100. For example, the management node 112can generate node pools and manage which virtual storage units aremapped to which nodes. The management node 112 may also manage whichstorage nodes 102 a-e have write-back caching enabled or disabled, asdescribed below.

In some examples, the management node 112 can receive the statuscommunications from the storage nodes 102 a-e and determine a subset ofstorage nodes 102 a-c that have the specialized hardware 108 a-c basedon the status information in the status communications. The specializedfunctionality of the specialized hardware 108 a-c can then be enabled onthe subset of storage nodes 102 a-c. For example, the management node112 can transmit signals, such as signal 118, to the subset of storagenodes 102 a-c for causing the storage nodes 102 a-c to enable thespecialized functionality. Each signal can include a command or otherinformation configured to cause a corresponding storage node to enablethe specialized functionality. For instance, the storage nodes 102 a-cmay be in a first state in which the specialized functionality isdisabled. To enable the specialized functionality on the storage nodes102 a-c, the management node 112 can transmit signals with activationcommands to the storage nodes 102 a-c. The storage nodes 102 a-c canreceive the signals, detect the activation commands in the signals, andresponsively switch from the first state to a second state in which thespecialized functionality is enabled. In other examples, at least someof the storage nodes 102 a-c may automatically enable the specializedfunctionality in response to determining that they have back thespecialized hardware 108 a-c. In still other examples, a systemadministrator may manually enable the specialized functionality on atleast some of the storage nodes 102 a-c based on determining that thestorage nodes 102 a-c have specialized hardware 108 a-c. By using one ormore of the above techniques, the specialized functionality can beenabled on the storage nodes 102 a-c.

With the specialized functionality engaged on the subset of storagenodes 102 a-c, the management node 112 can assign the subset of storagenodes 102 a-c to a node pool 122. A node pool can be a defined group ofstorage nodes configured to implement storage functionality to serviceone or more read/write requests. In this example, the node pool 122 onlyincludes the storage nodes 102 a-c that have the specialized hardware108 a-c. The node pool 122 may be designated as a higher-tiered pool,since it may have better performance characteristics than another nodepool (e.g., formed from storage nodes 102 d-e) that lacks thespecialized hardware or specialized functionality.

A user can obtain access to the node pool 122 for storing data. Forexample, a user may purchase a subscription to the node pool 122,allowing the user to store and retrieve data therefrom by submittingdata requests. Upon the user being granted such access, the distributedstorage system 100 can cause the node pool 122 to perform thespecialized functionality in relation to the data requests submitted bythe user. The specialized functionality may yield better performance orsecurity than is otherwise possible absent the specializedfunctionality.

In some examples, storage nodes may have more than one type ofspecialized hardware or may have specialize hardware capable ofimplementing more than one type of specialized functionality. In somesuch examples, the management node 112 can group together storage nodeshaving the same amounts and/or types of specialized functionality intothe same node pool. For example, the distributed storage system 100 caninclude a first set of storage nodes with specialized hardware forimplementing both data encryption and data compression. The distributedstorage system 100 can also include a second set of storage nodes withspecialized hardware for implementing data encryption but not datacompression. And the distributed storage system 100 include a third setof storage nodes with specialized hardware for implementing datacompression but not data encryption. As a result, the first set ofstorage nodes may be grouped into a first node pool capable ofimplementing both data encryption and data compression. The second setof storage nodes may be grouped into a second node pool capable ofimplementing data encryption but not data compression. And the third setof storage nodes may be grouped into a third node pool capable ofimplementing data compression but not data encryption. A user maypurchase a subscription to whichever of the node pools meets the user'sneeds, where the first node pool may be more expensive than the secondnode pool or the third node pool.

It will be appreciated that FIG. 1 is intended to be illustrative andnon-limiting. Other examples may include more components, fewercomponents, different components, or a different arrangement of thecomponents shown in FIG. 1 . For instance, although the distributedstorage system 100 includes five storage nodes in the example of FIG. 1, the distributed storage system 100 may have hundreds or thousands ofstorage nodes in other examples.

FIG. 2 is a sequence diagram of an example of a process for enablingspecialized functionality on distributed storage nodes according to someaspects of the present disclosure. Although the example shown in FIG. 2includes a certain sequence of steps, other examples may involve moresteps, fewer steps, different steps, or a different order of the stepsshown in FIG. 2 .

The process begins with a management node 112 of a distributed storagesystem transmitting a request for status information to a storage node102. The storage node 102 can receive the request and responsivelydetermine if specialized hardware is coupled to the storage node. Inthis example, the storage node 102 has determined that the specializedhardware is coupled to the storage node 102. Next, the storage node 102can transmit a response to the request, where the response is in theform of a status communication with status information indicating thatthe storage node 102 is coupled to the specialized hardware. Themanagement node 112 can receive the status communication and determinethat the storage node 102 is coupled to the specialized hardware basedon the status information. The management node 112 may then transmit asignal to the storage node 102 for causing the storage node 102 toenable the specialized functionality of the specialized hardware. Thestorage node 102 can receive the signal and responsively enable thespecialized functionality.

In some examples, the distributed storage system can use the storagenode 102 to service a data request. The data request may be ahigher-priority data request for which the specialized functionality maybe desirable. A data request may be higher-priority if it is morecritical, demanding, or higher cost than other data requests. Forexample, a user may pay a premium for the user's data requests to bedeemed higher priority.

FIG. 3 is a block diagram of an example of a migration process in adistributed storage system 100 according to some aspects of the presentdisclosure. In this example, the distributed storage system 100 includesa first node pool 302 for servicing data requests 308 from a clientdevice, such as a laptop computer, desktop computer, server, or mobiledevice. The client device may be external to the distributed storagesystem 100. Within the first node pool 302 is a storage node 102 d thatlacks specialized hardware. As a result, the storage node 102 d may beincapable of implementing the specialized functionality corresponding tothe specialized hardware. The storage node 102 d may include any numberof virtual storage units (VSU) 306 d. Virtual storage units can belogical devices that are mapped to physical storage devices for readingand writing data associated with data requests. The node locations andphysical storage-device mappings of the VSUs in the distributed storagesystem 100 may be adjustable by the management node 112.

It may be desirable for the data requests 308 to be serviced by storagenodes that have the specialized functionality enabled, for example toobtain the performance or security improvements associated with thespecialized functionality. For example, if the data requests 308 arehigher priority, it may be desirable to service the data requests 308using higher-performance storage nodes that have the specializedfunctionality enabled. To that end, the management node 112 can generatea second node pool 304 using the techniques described above, where thesecond node pool 304 includes storage nodes 102 a-b on which thespecialized functionality is enabled. The specialized functionality maybe enabled on the storage nodes 102 a-b based on the storage nodes 102a-b having corresponding specialized hardware 108 a-b. The managementnode 112 can determine that VSU 306 d_1 corresponds to (e.g., is adestination for) the data requests 308, and then migrate a VSU 306 d_1from storage node 102 d to storage node 102 a. This migration isrepresented in FIG. 1 by a dashed arrow. The management node 112 canalso transmit a communication to the client device from which the datarequests 308 originated, to notify the client device of the change inlocation of the VSU 306 d_1. As a result, the client device can directfuture data requests 308 corresponding to VSU 306 d_1 to storage node102 a, so that the data requests 308 can be serviced by the second nodepool 304 using the specialized functionality.

As one particular example, the management node 112 can determine thatthe data requests 308 have a particular priority level, such as a highpriority level associated with sensitive data. Different data requests308 may have different priority levels assigned by a user or the system.The management node 112 can also determine a VSU 306 d_1 associated withthe data requests 308 is located on a particular storage node 102 d ofthe distributed storage system 100. The management node 112 cancommunicate with the particular storage node 102 d to determine that theparticular storage node 102 d lacks a specialized storage adapter withinline data-encryption capabilities. For example, the management node112 can receive status information from the particular storage node 102d indicating that the particular storage node 102 d lacks thespecialized storage adapter. Since the particular storage node 102 dlacks the specialized storage adapter, the storage node 102 d is likelyincapable of implementing the inline data-encryption. Based ondetermining that (i) the data requests 308 have the particular prioritylevel and (ii) the particular storage node 102 d having the VSU 306 d_1associated with the data requests 308 does not have the specializedhardware, the management node 112 can migrate the VSU 306 d_1 from theparticular storage node 102 d to another storage node 102 a that has thespecialized hardware 108 a. As a result, the data requests 308 can beserviced by the other storage node 102 a using the specializedfunctionality moving forward, given the presence of the specializedhardware 108 a.

It will be appreciated that FIG. 3 is intended to be illustrative andnon-limiting. Other examples may include more components, fewercomponents, different components, or a different arrangement of thecomponents shown in FIG. 3 . For instance, although the distributedstorage system 100 includes three storage nodes in two node pools in theexample of FIG. 3 , the distributed storage system 100 may have anynumber of storage nodes spread across any number of node pools.

FIG. 4 is a block diagram of another example of a distributed storagesystem 400 according to some aspects of the present disclosure. Thedistributed storage system 400 includes a management node 112 andstorage nodes 102 a-e with specialized hardware 108 a-c.

In this example, the management node 112 includes a processor 402communicatively coupled with a memory 404. The processor 402 can includeone processor or multiple processors. Non-limiting examples of theprocessor 402 include a Field-Programmable Gate Array (FPGA), anapplication-specific integrated circuit (ASIC), a microprocessor, etc.The processor 402 can execute instructions 406 stored in the memory 404to perform operations. The instructions 406 can includeprocessor-specific instructions generated by a compiler or aninterpreter from code written in any suitable computer-programminglanguage, such as C, C++, C#, etc.

The memory 404 can include one memory or multiple memories. Non-limitingexamples of the memory 404 can include electrically erasable andprogrammable read-only memory (EEPROM), flash memory, or any other typeof non-volatile memory. At least some of the memory 404 includes anon-transitory computer-readable medium from which the processor 402 canread the instructions 406. The non-transitory computer-readable mediumcan include electronic, optical, magnetic, or other storage devicescapable of providing the processor 402 with computer-readableinstructions or other program code. Examples of the non-transitorycomputer-readable medium can include magnetic disks, memory chips, ROM,random-access memory (RAM), an ASIC, optical storage, or any othermedium from which a computer processor can read the instructions 406.

The processor 402 of the management node 112 can execute theinstructions 406 to perform operations. In particular, the processor 402can determine a subset of storage nodes 102 a-c that include specializedhardware 108 a-c based on status information 410 received from aplurality of storage nodes 102 a-e of the distributed storage system400. For example, the processor 402 can receive the status information410 from the plurality of storage nodes 102 a-e. The status information410 can indicate whether each storage node in the plurality of storagenodes 102 a-e has (e.g., is coupled to) a corresponding piece ofspecialized hardware. For example, the status information 410 canindicate that storage nodes 102 a-c have specialized hardware 108 a-c,and that storage nodes 102 d-e does not have the specialized hardware.Based on the status information 410, the processor 402 can determine asubset of storage nodes 102 a-c, from among the plurality of storagenodes 102 a-e, having the specialized hardware 108 a-c. The processor402 can then generate a node pool 122 that includes the subset ofstorage nodes 102 a-c. The specialized functionality 408 a-c can beenabled on the subset of storage nodes 102 a-c. The node pool 122 can beconfigured to perform the specialized functionality 408 a-c in relationto a data request 412.

In some examples, the processor 402 can implement some or all of thesteps shown in FIG. 5 . Other examples can include more steps, fewersteps, different steps, or a different order of the steps than is shownin FIG. 5 . The steps of FIG. 5 are discussed below with reference tothe components discussed above in relation to FIG. 4 .

In block 502, a processor 402 determines a subset of storage nodes 102a-c that include specialized hardware 108 a-c. The specialized hardware108 a-c can be preconfigured with specialized functionality 408 a-c forcompressing data or encrypting data, in some examples. The processor 402can determine the subset of storage nodes 102 a-c based on statusinformation 410 received from the plurality of storage nodes 102 a-e ofa distributed storage system 400. The status information 410 canindicate whether each storage node in the plurality of storage nodes 102a-e has a corresponding piece of specialized hardware.

In block 504, the processor 402 generates a node pool 122 that includesthe subset of storage nodes 102 a-c with the specialized hardware 108a-c. In some examples, generating the node pool 122 may involvetransmitting one or more commands to an application programminginterface (API) of the distributed storage system 100 for causing thedistributed storage system 100 to assign the storage nodes into the nodepool 122.

After the node pool 122 is generated, the node pool 122 can perform thespecialized functionality in relation to a data request 412. Forexample, data request 412 can correspond to a particular VSU that ispart of the node pool 122. As a result, the data request 412 can beserviced by the node pool 122 using the specialized functionality.

The foregoing description of certain examples, including illustratedexamples, has been presented only for the purpose of illustration anddescription and is not intended to be exhaustive or to limit thedisclosure to the precise forms disclosed. Numerous modifications,adaptations, and uses thereof will be apparent to those skilled in theart without departing from the scope of the disclosure. For instance,any examples described herein can be combined with any other examples toyield further examples.

The invention claimed is:
 1. A management node of a distributed storagesystem, the management node comprising: a processor; and a memoryincluding instructions that are executable by the processor for causingthe processor to: receive status information from a plurality of storagenodes of the distributed storage system, the plurality of storage nodesbeing separate from the management node, and the status informationindicating which storage nodes of the plurality of storage nodes includespecialized hardware that is preconfigured with specializedfunctionality for compressing data or encrypting data; identify, basedon the status information, a subset of storage nodes that include thespecialized hardware from among the plurality of storage nodes; inresponse to identifying the subset of storage nodes that include thespecialized hardware, group the subset of storage nodes together into anode pool that includes the subset of storage nodes with the specializedhardware, the node pool being configured to perform the specializedfunctionality in relation to a data request; determine that a particulardata request has a particular priority level; determine that aparticular virtual storage unit (VSU) associated with the particulardata request is located on a particular storage node of the distributedstorage system; determine, based on the status information, that theparticular storage node does not have the specialized hardware; andbased on determining that the particular data request has the particularpriority level and that the particular storage node does not have thespecialized hardware, migrate the particular VSU from the particularstorage node to another storage node of the distributed storage systemthat has the specialized hardware.
 2. The management node of claim 1,wherein each storage node in the plurality of storage nodes isconfigured to determine whether the storage node includes a respectivepiece of specialized hardware and responsively transmit a statuscommunication to the management node, the status communication includingrespective status information indicating whether the storage nodeincludes the respective piece of specialized hardware.
 3. The managementnode of claim 1, wherein the node pool consists only of the storagenodes in the subset.
 4. The management node of claim 1, wherein thememory further includes instructions that are executable by theprocessor for causing the processor to transmit signals to the subset ofstorage nodes for causing each storage node in the subset of storagenodes to enable the specialized functionality.
 5. The management node ofclaim 4, wherein the signals are configured to cause each storage nodein the subset of storage nodes to switch from (i) a first state in whichthe specialized functionality is disabled to (ii) a second state inwhich the specialized functionality is enabled.
 6. The management nodeof claim 1, wherein the specialized hardware is manufactured withspecialized circuitry for implementing the specialized functionality,prior to the specialized hardware being incorporated into thedistributed storage system.
 7. A method comprising: receiving, by aprocessing device of a management node of a distributed storage system,status information from a plurality of storage nodes of the distributedstorage system, the plurality of storage nodes being separate from themanagement node, and the status information indicating which storagenodes of the plurality of storage nodes include specialized hardwarethat is preconfigured with specialized functionality for compressingdata or encrypting data; identifying, by the processing device and basedon the status information, a subset of storage nodes that include thespecialized hardware from among the plurality of storage nodes; inresponse to identifying the subset of storage nodes that include thespecialized hardware, grouping, by the processing device, the subset ofstorage nodes together to form a node pool that includes the subset ofstorage nodes with the specialized hardware, the node pool beingconfigured to perform the specialized functionality in relation to adata request; determining, by the processing device, that a particulardata request has a particular priority level; determining, by theprocessing device, that a particular virtual storage unit (VSU)associated with the particular data request is located on a particularstorage node of the distributed storage system; determining, by theprocessing device and based on the status information, that theparticular storage node does not have the specialized hardware; andbased on determining that the particular data request has the particularpriority level and that the particular storage node does not have thespecialized hardware, migrating, by the processing device, theparticular VSU from the particular storage node to another storage nodeof the distributed storage system that has the specialized hardware. 8.The method of claim 7, wherein each storage node in the plurality ofstorage nodes is configured to determine whether the storage nodeincludes a respective piece of specialized hardware and responsivelytransmit a status communication, the status communication includingrespective status information indicating whether the storage nodeincludes the respective piece of specialized hardware.
 9. The method ofclaim 7, wherein the node pool consists only of the storage nodes in thesubset.
 10. The method of claim 7, further comprising transmittingsignals to the subset of storage nodes for causing each storage node inthe subset of storage nodes to enable the specialized functionality. 11.The method of claim 7, wherein the specialized hardware includes astorage adapter, a storage device, an input/output (I/O) interface, or aprocessing device, and wherein the specialized hardware has built-incircuitry configured for implementing data encryption or datacompression.
 12. The method of claim 7, further comprising: determining,based on the status information, that a storage node of the plurality ofstorage nodes does not have the specialized hardware; and excluding thestorage node from the node pool based on determining that the storagenode does not have the specialized hardware.
 13. A non-transitorycomputer-readable medium comprising program code that is executable by aprocessor for causing the processor to: receive status information froma plurality of storage nodes of a distributed storage system, the statusinformation indicating which storage nodes of the plurality of storagenodes include specialized hardware that is preconfigured withspecialized functionality for compressing data or encrypting data;identify, based on the status information, a subset of storage nodesthat include the specialized hardware from among the plurality ofstorage nodes; in response to identifying the subset of storage nodesthat include the specialized hardware, group the subset of storage nodestogether to form a node pool that includes the subset of storage nodeswith the specialized hardware, the node pool being configured to performthe specialized functionality in relation to a data request; determinethat a particular data request has a particular priority level;determine that a particular virtual storage unit (VSU) associated withthe particular data request is located on a particular storage node ofthe distributed storage system; determine, based on the statusinformation, that the particular storage node does not have thespecialized hardware; and based on determining that (i) the particulardata request has the particular priority level and (ii) the particularstorage node does not have the specialized hardware, migrate theparticular VSU from the particular storage node to another storage nodeof the distributed storage system that has the specialized hardware. 14.The non-transitory computer-readable medium of claim 13, wherein eachstorage node in the plurality of storage nodes is configured todetermine whether the storage node includes a respective piece ofspecialized hardware and responsively transmit a status communication,the status communication including respective status informationindicating whether the storage node includes the respective piece ofspecialized hardware.
 15. The non-transitory computer-readable medium ofclaim 13, further comprising program code that is executable by theprocessor for causing the processor to transmit signals to the subset ofstorage nodes for causing each of storage node in the subset of storagenodes to enable the specialized functionality.
 16. The non-transitorycomputer-readable medium of claim 13, further comprising program codethat is executable by the processor for causing the processor to:determine, based on the status information, that a storage node of theplurality of storage nodes does not have the specialized hardware; andexclude the storage node from the node pool based on determining thatthe storage node does not have the specialized hardware, wherein thenode pool consists only of storage nodes having the specializedfunctionality enabled.
 17. The management node of claim 1, wherein eachstorage node in the plurality of storage nodes is a server.
 18. Themanagement node of claim 1, wherein the memory further includesinstructions that are executable by the processor for causing theprocessor to group the subset of storage nodes together into the nodepool by transmitting one or more commands to an application programminginterface associated with the distributed storage system.
 19. The methodof claim 7, wherein grouping the subset of storage nodes together intothe node pool comprises transmitting one or more commands to anapplication programming interface associated with the distributedstorage system.
 20. The non-transitory computer-readable medium of claim13, further comprising program code that is executable by the processorfor causing the processor to: group the subset of storage nodes togetherinto the node pool by transmitting one or more commands to anapplication programming interface associated with the distributedstorage system.